Spintronics

Summer Scholar Grant Smith looks into a sputter deposition chamber, where he makes ultrathin films — from 2 to 10 nanometers thick — of magnetic materials suitable for spin-based electronics such as those used in computer memory systems.

Booting up spin-based device studies

Summer Scholar Grant Smith works to establish parameters for making ferromagnetic thin films in the Luqiao Liu lab.

August 15, 2016

At left: A single crystal compound of gadolinium, platinum, and bismuth made with naturally occurring elements. At right, a single crystal of this material made with isotopically enriched gadolinium for neutron scattering experiments. Both crystals are approximately 1 mm in size.

Mixing topology and spin

MIT-led team demonstrates paired topology and intrinsic magnetism in compound combining gadolinium, platinum, and bismuth.

July 19, 2016

Arrows indicate the spin direction in the ferromagnetic insulator (EuS, shown in red) and topological insulator (Bi2Se3, shown in blue) at the interface between the two materials.

Researchers find unexpected magnetic effect

Combining two thin-film materials yields surprising room-temperature magnetism.

May 9, 2016

MIT postdoc Cui-Zu Chang works with equipment that can monitor topological insulator thin-film quality as it grows. The bright green vertical bar on computer screen is an indicator of very high-quality film growth. Chang led work in the Moodera group showing the first zero-resistance edge state in a circuit.

Achieving zero resistance in energy flow

MIT postdoc Cui-Zu Chang makes a spintronic breakthrough in the Moodera group.

May 6, 2016

MIT Senior Research Scientist Jagadeesh Moodera stands in front of a custom-built system used to fabricate ultrathin films. His work includes devices that exhibit resistance-free, spin-polarized electrical current; enabling memory storage at the level of single molecules; and the search for the elusive Majorana fermions sought for quantum computing.

Research highlight: Jagadeesh Moodera

Step-by-step, the Moodera Research Group is building the essential knowledge and hardware for next-generation quantum computers.

April 29, 2016

How to make large 2-D sheets

MIT-led team develops method for scaling up production of thin electronic material.

September 21, 2015

This diagram shows the layered structure analyzed for its magnetic properties. Yellow spheres represent tellurium atoms; light blue spheres represent antimony-bismuth; and purple spheres represent sulfur. The black sphere with an arrow represents an atom of dopant, and green spheres with arrows show atoms of europium. Different colored arrows show various ways an europium ion can be affected by th...

Unusual magnetic behavior observed at a material interface

Findings could lead to a building block for future quantum computers, and a research tool for physics.

August 18, 2015

Magnetic tunnel junctions hidden under cones of tungsten

Spin designers

Caroline Ross and Geoffrey Beach are studying how the “spin” of electrons on nanomagnets could be manipulated to create faster, more energy-efficient computers.

January 7, 2015

The internal molecular structure of the electrode compound reveals what the researchers call the "superstructure." At right is a scanning transmission electron microscope image of the material, and, at left, the image is color-coded based on electrical properties: Each green dot stands for a stripe of manganese plus-4 ions; purple dots, for manganese plus-3 ions; and mixed color dots (green inside...

Team visualizes complex electronic state

Multidisciplinary group solves mystery of how a potential battery electrode material behaves.

May 18, 2014

The new molecules are known as 'graphene fragments,' because they largely consist of flat sheets of carbon (which are attached to zinc atoms). That makes them easier to align during deposition, which could simplify the manufacture of molecular memories.

Storing data in individual molecules

An international team of researchers demonstrates the possibility of molecular memory near room temperature.

January 23, 2013

Elementary particles have a fundamental property called 'spin' that determines how they align in a magnetic field. MIT researchers have created a new physical system in which atoms with clockwise spin move in only one direction, while atoms with counterclockwise spin move in the opposite direction.

A one-way street for spinning atoms

Work correlating ultracold atoms’ spin with their direction of motion may help physicists model new circuit devices and unusual phases of matter.

August 30, 2012

This diagram illustrates how lasers can be used to control an electric current on these new materials. Electrons (blue spheres) travel, as if on a highway, in different directions, with their axis of spin (arrows) aligned differently according to the direction of travel. A circularly polarized laser beam (left) affects only electrons going in one direction, removing them from the flow, leaving a n...

Electronics takes on a new spin

Researchers at MIT find a way to observe and control the way electrons spin on the surface of exotic new materials.

December 5, 2011

MIT News | Massachusetts Institute of Technology

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